Bone joint reaming tool

ABSTRACT

A sacroiliac joint fusion screw and associated delivery tools and method. Embodiments of the sacroiliac joint fusion screw comprise a shaft having proximal and distal end portions and a head on the proximal end of the shaft. A threaded portion on a distal portion of the shaft is configured to engage a sacrum. A glide zone portion on the shaft between the threaded portion and the proximal end portion is configured to extend through an ilium. The screw can provide stability and compression to the joint.

CROSS REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. application Ser. No.14/790,480, filed Jul. 2, 2015 and entitled Sacroiliac Joint FusionScrew And Method, which claims the benefit of U.S. ProvisionalApplication Ser. No. 62/020,528 filed on Jul. 3, 2014 and entitledSacroiliac Joint Fusion Screw And Method, which are incorporated hereinby reference in their entireties and for all purposes.

TECHNICAL FIELD

The invention relates to surgical fasteners, instruments and methods. Inparticular, embodiments of the invention include screws, tools andmethods for use in connection with sacroiliac joint fusion.

BACKGROUND

The sacroiliac joint is formed by the meeting of the sacrum (at the baseof the spine) and the ilium (at the upper part of the pelvis). Treatmentfor indications such a pain at the sacroiliac joint includes fusing thesacrum and ilium together. The Assell et al. U.S. Patent ApplicationPublication No. 2011/0166575, for example, discloses a sacroiliac fusionsystem including associated surgical instruments and methods. A bonescrew that can be used in connection with sacroiliac fusion proceduresis disclosed in the Assell et al. U.S. Patent Application PublicationNo. 2012/0323285. Both of the above-identified Assell patent applicationpublications are incorporated herein by reference for all purposes.There remains a continuing need for improved sacroiliac joint fusionfasteners (such as screws) and associated instruments and procedures.

SUMMARY

Embodiments of the invention include improved sacroiliac joint fusionscrews and associated delivery tools and methods. Embodiments of thesacroiliac joint fusion screw comprise a shaft having proximal anddistal end portions and a head on the proximal end of the shaft. Athreaded portion on a distal portion of the shaft is configured toengage a sacrum. A glide zone portion on the shaft between the threadedportion and the proximal end portion is configured to extend through anilium. The screw can provide stability and compression to the joint.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an isometric illustration of a joint fusion screw inaccordance with embodiments of the invention.

FIG. 2 is an illustration of a sacroiliac joint fused by the screw shownin FIG. 1 by methods in accordance with embodiments of the invention.

FIGS. 3A and 3B are side and end views, respectively, of a reaminginstrument in accordance with embodiments of the invention, in adelivery or insertion state.

FIGS. 4A and 4B are side and end views, respectively, of the reaminginstrument shown in FIGS. 3A and 3B, in an operational state.

FIG. 5 is a side view of bone graft application tool in accordance withembodiments of the invention.

FIGS. 6A-6H are diagrammatic illustrations of steps in accordance withembodiments of the invention for using the instruments shown in FIGS.3A, 3B, 4A, 4B and 5 to insert the joint fusion screw shown in FIG. 1.

DESCRIPTION OF THE INVENTION

FIG. 1 illustrates a fastener or screw 10 in accordance with embodimentsof the invention. As shown, screw 10 includes a shank or shaft 12 havinga first or proximal end with a head 14 and a second or distal end with atip 16. A threaded portion 17 of the shaft 12 adjacent to the tip 16(i.e., on a distal portion of the shaft) includes threads 18. A glidezone portion 20 of the shaft 12 adjacent to the head 14 (i.e., on aproximal portion of the shaft) is free from threads and in theillustrated embodiment has a generally smooth surface 22. Theillustrated embodiment of the screw 10 also includes cutting threads 24at the proximal end of the threaded portion 17 (e.g., adjacent to theglide zone portion 20) to facilitate removal of the screw 10. Otherembodiments of the invention do not have the cutting threads 24.Similarly, embodiments of screw 10 (not shown) have self-tapping threadsat the distal end of threaded portion 17 (i.e., near the tip 16). Head14 includes a hex socket 26 that is configured to receive a hex keydriver tool (not shown) that can be used to implant the screw 10. Otherembodiments of the invention (not shown) include a head 14 having otherdriver tool-receiving structures such as a hex head or a hex cap.

Screw 10 can be fabricated from metal such as titanium or other suitablematerials. The screw 10 can have any length suitable for the sacroiliacjoint fusion applications. Embodiments of the screw 10 can, for example,have lengths from 45 mm to 95 mm at 5 mm increments. The diameter of theshaft 12 (i.e., a minor diameter) can be about 10 mm and the diameter ofthe threaded portion 17 (i.e., a major diameter at the threads 18) canbe about 16 mm in embodiments. Other embodiments have larger and smallermajor and minor diameters. Thread pitch ranges from about 2.25 mm to 2.5mm, and thread depth ranges from about 2.8 mm to about 3 mm inembodiments, although the screws 10 can have larger and smaller threadpitch and depth. Screws 10 can also be cannulated. Some embodiments ofscrews 10 can, for example, have a cannula of about 2.5 mm in diameter,although other embodiments have larger and smaller openings. Head 14will typically have a diameter that is larger than the diameter of theshaft 12. For example, some embodiments of screw 10 have a head 14 thatis about 18 mm in diameter, although other embodiments have heads withlarger or smaller diameter heads.

As described below, a function of the threaded portion 17 of the screw10 is to engage the sacrum when implanted into the sacroiliac joint fromthe side of the ilium. Accordingly, the length of the threaded portion17 can vary. A function of the glide zone portion 20 is to enable thescrew 10 to provide compression to the sacroiliac joint. This functioncan be achieved by providing the screw 10 with glide zone lengthscorresponding to the thickness of the ilium when the screw is implantedin the sacroiliac joint (i.e., the portion of the screw 10 that extendsthrough and is adjacent to the ilium is free from threads). In oneembodiment, the length of the glide zone portion is about 23 mm. Thelength of the glide zone portion 20 can be longer or shorter in otherembodiments. The length of the glide zone portion 20 can be determinedby measuring widths of ilia of patients (e.g., from CT scans) at thelocations of the sacroiliac joint to be fused, and averaging thosewidths.

FIG. 2 illustrates a sacroiliac joint 40 fused by a screw 10 inaccordance with embodiments of the invention. As shown, the sacroiliacjoint 40 includes portions of an ilium 42 and a sacrum 44. The joint 40is typically approached from the side with the ilium 42. Using a toolsuch as a drill (not shown), a pilot hole is bored through the ilium 42and into the sacrum 44 at the location to be fused. A decorticationprocedure can optionally be performed to remove tissue from the ilium 42and/or sacrum 44 in an area 46 (i.e., a decortication region) of thejoint 40 to be fused (e.g., using a reamer or other tool such as thatshown in application publication 2011/0166575 referred to above that isinserted into the pilot hole). Bone graft material can optionally beinserted into the area 46 (not shown).

Screw 10 can then be implanted into the joint 40 by using a driver toinsert the screw into the pilot hole. As shown in FIG. 2, the threadedportion 17 of the screw 10 engages the sacrum 44, and the glide zoneportion 20 extends through the ilium 42. Because the threaded portion 17of the screw 10 is in purchase with the sacrum 44 and the head 14 isengaged with the ilium 42 while the portions of the ilium that the screwpasses through are free from threads 18, the screw provides compressionof the joint (i.e., the ilium and sacrum are urged together by thescrew). In the illustrated embodiment a washer 50 is located on theshaft 12 between the screw head 14 and the ilium to increase the surfacearea of the engagement by the screw head. The compression provided bythe screw 10 when implanted in accordance with the method describedabove allows significant compression across the sacroiliac joint 40.This enhanced compression can provide immediate patient comfort.Stability and joint preparation are also provided by this fusion methodand device. For example, when using a screw such as 10 having a shaft 12with a major diameter of 16 mm and a minor diameter of 10 mm, and a head14 having an 18 mm diameter, an effective fusion radius of about 30 mm(14130 mm³) can be achieved.

The amount of compression provided by the screw 10 can be maximized ifthe entire portion of the ilium 42 through which the screw 10 extends isfree from purchase by threads 18. However, in some embodiments of theinvention (not shown), substantial or efficacious amounts of compressioncan be achieved even if portions of the ilium 42 are purchased bythreaded portion 17 of the screw. Should it be desired to remove screw10, the cutting threads 24 will facilitate the removal by forming aleading path for the threads 18 between the cutting threads 24 and tip16.

Additional apparatus and methods in connection with the invention aredisclosed in the Appendix of the provisional application No. 62/020,528identified above and incorporated herein by reference.

FIGS. 3A and 3B illustrate side and end views, respectively, of areaming tool 60 in accordance with embodiments of the invention in adelivery state. FIG. 3A is a partial cross sectional view. FIGS. 4A and4B illustrate side and end views, respectively, of the tool 60 in anoperational state. As shown, the tool 60 has a central shaft 62 with adistal end 64, and a cutter 66 mounted to the shaft. The illustratedembodiment of cutter 66 has a mounts 68 coupled to the shaft 62, and aplurality of cutting blades 70 extending between the mounts. As shown,the opposite ends of the blades 70 are mounted to the mounts 68. Blades70 are nitinol in embodiments, but can be other materials in otherembodiments. In the delivery state shown in FIGS. 3A and 3B, the cutter66 has a first, reduced diameter (e.g., about 10 cm in embodiments,generally equal to the minor diameter of the screw 10), with blades 70in a generally linear configuration parallel one another and to thecentral shaft 62. As described below, when the reaming tool 60 isinserted into a surgical site at a sacroiliac joint and the cutter 66 isactuated, one or both of the mounts 68 move toward the other on theshaft 62, causing the blades 70 to deploy and flex outwardly to anon-linear configuration extending beyond the mounts 68, and the cutter66 to take on a second, expanded diameter configuration (e.g., about 26mm in embodiments) in the operational state shown in FIGS. 4A and 4B. Inthe illustrated embodiment the blades 70 have a generally triangularprofile when the cutter 66 is deployed to the operational state, and themount 68 that is adjacent to the distal end 64 slides toward the othermount (which can be fixed) to position the cutter at a predeterminedlocation with respect to the distal end 64 of the tool 60. The locationof the cutter 66 in the surgical site can thereby be more accuratelydetermined. The embodiment shown in FIG. 4A has a shoulder member 72that extends from the shaft 62 at a predetermined distance such as 1 cmfrom the distal end 64. The shoulder member 72 can aid in thepositioning of the cutter 66. Other embodiments (not shown) include anactuator for moving the cutter 66 between the delivery and operationalstates.

FIG. 5 is a partial cross sectional illustration of a bone graftapplication tool 80 in accordance with embodiments of the invention. Theillustrated embodiment of the tool 80 has a shaft 82 with a distal end84, a body 86 with a chamber 88 and one or more delivery openings 90(two are shown in FIG. 5), and a plunger 92 in the chamber 88. Thediameter of the body 86 can be about equal to the minor diameter of thescrew 10 (e.g., about 10 mm). The body 86 has a shoulder 94 positionedat a location with respect to the distal end 84 that will locate thedelivery openings 90 at locations corresponding to voids created by thereaming tool 60 in sacroiliac joints (e.g., the openings 90 of can belocated at about the same distance from the distal end 84 of tool 80 asthe expanded diameter portion of the cutter 66 is located from thedistal end 64 of the reaming tool 60). As shown in FIG. 5, the deliveryopenings 90 extend from the exterior of the body 86, and communicatewith the chamber 88. As described below, during sacroiliac joint fusionprocedures, bone graft material (e.g., autograft material from initialdrilling into bone of the patient) can be inserted into the chamber 88,and the plunger 92 actuated to deliver the bone graft material to thefusion site through the openings 90.

A sacroiliac joint fusion method in accordance with embodiments of theinvention can be described with reference to FIGS. 6A-6H. As shown inFIG. 6A, a pin 100 can be inserted through the ilium 42 and into thesacrum 44 to define a path to the joint at the desired fusion surgicalsite. Using the pin 100 as a guide path, a drill 102 (e.g., 10.25 mm indiameter in embodiments) can be used to bore a pilot hole through theilium 42 and sacrum 44 at the fusion site (FIG. 6B). The ilium 42 and/orsacrum 44 can be decorticated at the fusion site. FIGS. 6C and 6D, forexample, illustrate the use of reaming tool 60 for decortication. Asshown in FIG. 6C, the reaming tool 60 is inserted into the pilot holewith the cutter 66 in the delivery state. When the tool 60 ismanipulated to locate cutter 66 at the desired position, the tool 60 isactuated to deploy the cutter to its operational state, and the tool isactuated (e.g., rotated) to remove portions of the ilium 42 and/orsacrum 44. Following the decortication procedure the reaming tool 60 isactuated to return the cutter 66 to the delivery state, and the reamingtool is withdrawn from the patient. Bone graft material, for exampleautograft bone material collected from the patient during the boringstep 6B and/or the decortication step 6D, can be inserted at the fusionsite. FIG. 6E, for example, illustrates the use of bone graftapplication tool 80 to deliver bone graft material to the decorticatedarea of the fusion site. During the step illustrated generally by FIG.6E, the bone graft application tool 80 can be manipulated to positionthe delivery openings 90 at the location of any decorticated portions ofthe ilium 42 and sacrum 44.

As shown in FIG. 6F, an instrument such as 110 can be used to measurethe surgical site for purposes of determining an appropriate length forthe screw 10. A screw 10 suitable for the fusion site is then selected,and inserted using a driver as shown in FIG. 6G. FIG. 6H, like FIG. 2,diagrammatically illustrates the screw 10 fusing the ilium 42 and sacrum44 in accordance with embodiments of the invention. In embodiments,other methods are performed to insert screws 10. For example, inembodiments, the decortication and/or bone graft material delivery stepsare not performed, and other procedures can be performed.

Although the invention has been described with reference to preferredembodiments, those skilled in the art will recognize that changes can bemade in form and detail without departing from the spirit and scope ofthe invention.

The invention claimed is:
 1. A joint reaming tool, comprising: a shaft comprising a proximal portion, an elongate distal tip portion, and a distal end on the elongate distal tip portion, wherein the tool is configured to be inserted into a joint leading with the distal end; a shoulder on a proximal end of the elongate distal tip portion of the shaft, proximal of the distal end; a cutter on the shaft, proximal of the shoulder, the cutter movable between a reduced diameter delivery state and an enlarged diameter operational state, wherein the cutter is configured to create voids in a joint when in the operational state, and including: a plurality of cutting blades including proximal and distal end portions; and wherein the cutting blades are generally linear and parallel to one another when the cutter is in the delivery state, and the cutting blades expand outwardly to a non-linear cutting configuration proximal of the shoulder by the distal end portions of the cutting blades moving away from the shoulder and toward the proximal end portions of the blades when the cutter is in the operational state.
 2. The joint reaming tool of claim 1 wherein the cutting blades have a generally triangular cutting configuration profile when the cutter is in the operational state.
 3. The joint reaming tool of claim 2, and further comprising an actuator for moving the cutter between the delivery state and the operational state.
 4. The joint reaming tool of claim 1, further comprising a first mount moveable on the shaft, wherein the distal end portions of the cutting blades are mounted to the first mount, and the first mount moves toward the proximal end portion of the tool when the cutter is moved from the delivery state to the operational state.
 5. The joint reaming tool of claim 4 wherein the cutting blades have a generally triangular cutting configuration profile when the cutter is in the operational state.
 6. The joint reaming tool of claim 4, wherein the shoulder is configured to position the cutter.
 7. The joint reaming tool of claim 4, further comprising a second mount, and wherein the proximal end portions of the cutting blades are mounted to the second mount.
 8. The joint reaming tool of claim 7 wherein the second mount is fixedly positioned with respect to the shaft.
 9. The joint reaming tool of claim 8, wherein the shoulder is configured to position the cutter.
 10. The joint reaming tool of claim 9 wherein the cutting blades have a generally triangular cutting configuration profile when the cutter is in the operational state.
 11. The joint reaming tool of claim 1, further comprising locating structure to locate the position the cutter with respect to the shoulder when the cutter is in the operational state.
 12. The joint reaming tool of claim 1, further comprising for use with the joint reaming tool, a bone graft application tool comprising: a body; a chamber in the body to receive bone graft material; one or more delivery openings on the body in communication with the chamber; a shoulder on the body to locate the delivery openings at locations corresponding to the voids that can be created by the joint reaming tool in a joint.
 13. The joint reaming tool and bone graft application tool of claim 12, the bone graft application tool further comprising a plunger actuatable to deliver bone graft material from the chamber through the one or more delivery openings.
 14. The joint reaming tool and bone graft application tool of claim 12, wherein: the bone graft application tool further comprises a shaft extending from the body; and the shoulder of the bone graft application tool extends from the shaft.
 15. The joint reaming tool and bone graft application tool of claim 14, the bone graft application tool further comprising a plunger actuatable to deliver bone graft material from the chamber through the one or more delivery openings. 